Telemetric orthopaedic implant

ABSTRACT

An instrumented orthopaedic implant, such as an intramedullary (IM) nail, is disclosed. The implant has the capacity to provide an accurate measurement of the applied mechanical load across the implant. The implant includes sensors and associated electronic components located in recesses on the outer surface of the implant. The implant houses the sensing apparatus, the interface circuitry, the data transmitter, and the power receiver. The hermetically sealed housing is adapted for implantation in the body of a patient. The implant is used with a controller which communicates with it by telemetry, and there is an acting unit connected to the electronic components which is adapted to carry out a function based upon a condition detected by the sensors.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No. 12/064,546, filed Jul. 28, 2008, which is a National Phase of International Application No. PCT/US2006/033326, filed Aug. 23, 2006, which claims the benefit of: U.S. Provisional Application No. 60/710,550, filed on Aug. 23, 2005; U.S. Provisional Application No. 60/728,374, filed on Oct. 19, 2005; and U.S. Provisional Application No. 60/816,675, filed on Jun. 27, 2006. The disclosure of each application is incorporated by reference in its entirety.

BACKGROUND OF THE INVENTION

1. Field of the Invention

This invention relates generally to orthopaedic implants and, more particularly, orthopaedic implants having data acquisition capabilities.

2. Related Art

Trauma products, such as intramedullary (IM) nails, pins, rods, screws, plates and staples, have been used for many years in the field of orthopaedics for the repair of broken bones. These devices function well in most instances, and fracture healing occurs more predictably than if no implant is used. In some instances, however, improper installation, implant failure, infection or other conditions, such as patient non-compliance with prescribed post-operative treatment, may contribute to compromised healing of the fracture, as well as increased risk to the health of the patient.

Health care professionals currently use non-invasive methods, such as x-rays, to examine fracture healing progress and assess condition of implanted bone plates. However, x-rays may be inadequate for accurate diagnoses. They are costly, and repeated x-rays may be detrimental to the patient's and health care workers' health. In some cases, nonunions of fractures may go clinically undetected until implant failure. Moreover, x-rays may not be used to adequately diagnose soft tissue conditions or stress on the implant. In some instances, invasive procedures are required to diagnose implant failure early enough that appropriate remedial measures may be implemented.

The trauma fixation implants currently available on the market are passive devices because their primary function is to support the patient's weight with an appropriate amount of stability whilst the surrounding fractured bone heals. Current methods of assessing the healing process, for example radiography, patient testimonial, etc., do not provide physicians with sufficient information to adequately assess the progress of healing, particularly in the early stages of healing. X-ray images only show callus geometry and cannot access the mechanical properties of the consolidating bone. Therefore, it is impossible to quantify the load sharing between implant and bone during fracture healing from standard radiographs, CT, or MRI scans. Unfortunately, there is no in vivo data available quantifying the skeletal loads encountered during fracture healing as well as during different patient and physiotherapy activities. The clinician could use this information to counsel the patient on life-style changes or to prescribe therapeutic treatments if available. Continuous and accurate information from the implant during rehabilitation would help to optimize postoperative protocols for proper fracture healing and implant protection and add significant value in trauma therapy. Furthermore, improvements in security, geometry, and speed of fracture healing will lead to significant economic and social benefits. Therefore, an opportunity exists to augment the primary function of trauma implants to enhance the information available to clinicians.

Patient wellness before and after an intervention is paramount. Knowledge of the patient's condition can help the caregiver decide what form of treatment may be necessary given that the patient and caregiver are able to interact in an immediate fashion when necessary. Many times the caregiver does not know the status of a would-be or existing patient and, therefore, may only be able to provide information or incite after it was necessary. If given information earlier, the caregiver can act earlier. Further, the earlier information potentially allows a device to autonomously resolve issues or remotely perform the treatment based on a series of inputs.

Surgeons have historically found it difficult to assess the patient's bone healing status during follow up clinic visits. It would be beneficial if there was a device that allowed the health care provider and patient to monitor the healing cascade. Moreover, it would be beneficial if such a device could assist in developing custom care therapies and/or rehabilitation.

Additionally, surgeons have found it difficult to manage patient information. It would be beneficial if there was available a portable memory device that stored patient information, such as entire medical history files, fracture specifics, surgery performed, X-ray images, implant information, including manufacturer, size, material, etc. Further, it would be beneficial if such portable memory device could store comments/notes from a health care provider regarding patient check-ups and treatments given.

Therefore, there is a need in the art for an instrumented orthopaedic trauma implant that can provide precise and accurate information to doctors and patients concerning the status of the implant, progress of fracture healing, and the surrounding tissue without the need for x-rays or invasive procedures.

SUMMARY OF THE INVENTION

It is in view of the above problems that the present invention was developed. The invention is an instrumented orthopaedic implant, such as an intramedullary (IM) nail, with the capacity to provide an accurate measurement of the applied mechanical load across the implant. The implant includes sensors and associated electronic components for measurement of loads and transmission of the sensor data to an external reader.

One aspect of the invention is that it allows for information to be gathered and processed yielding conclusive valuable data with respect to a subject's bone healing cascade. The invention removes the guessing from the diagnosis by providing objective unbiased data collected from them throughout the healing process. Because the invention has a memory function, patient data can be stored; thus, allowing for the easy transmission of the data. The data may include personal data, patient history information, as well as patient activity. If the activity is captured, the surgeon could discern if the patient has been accurately performing postoperative rehabilitation regimens. This allows the surgeon to accurately predict and prescribe further regimens, which currently is not feasible with existing employed technology.

In another aspect of the invention, the captured information also can be used as an input to an algorithm that outputs a command for one or more reactions. The invention may react in a number of ways. The device enables the surgeon to allow autonomous intervention when needed to augment treatment using a biologic, such as injectable cements or demineralized bone matrix, to aid in the speed healing or informs the surgeon if a revision surgery may be necessary.

Thus, in furtherance of the above goals and advantages, the present invention is, briefly, a telemetric orthopaedic implant system, the system including an orthopaedic implant and a control unit. The orthopaedic implant includes at least one sensor; a first recess adapted to receive the at least one sensor; an electronic component electrically connected to the at least one sensor, the electronic component including at least a power supply, a first transmitter, a first receiver, and a first microprocessor; a second recess adapted to receive the electronic component; potting material to seal the first recess and the second recess; a power source electrically connected to the electronic component; and an acting unit electrically connected to the electronic component, the acting unit adapted to carry out a function based upon a condition. The control unit includes a second microprocessor; a second transmitter electrically connected to the second microprocessor, the second transmitter adapted to send a signal to the first receiver of the electronic component; and a second receiver electrically connected to the second microprocessor, the second receiver adapted to receive data from the first transmitter of the electronic component.

Further features, aspects, and advantages of the present invention, as well as the structure and operation of various embodiments of the present invention, are described in detail below with reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings, which are incorporated in and form a part of the specification, illustrate the embodiments of the present invention and together with the description, serve to explain the principles of the invention. In the drawings:

FIG. 1 is a perspective view of a telemetric orthopaedic implant in a first embodiment;

FIG. 2 is a top view of the implant shown in FIG. 1;

FIG. 3 is a partial sectional side view of the implant shown in FIG. 1;

FIG. 4 is a detailed perspective view of the implant shown in FIG. 1;

FIG. 5 is a perspective view of a telemetric orthopaedic implant in a second embodiment;

FIG. 6 is a perspective view of the telemetric orthopaedic implant shown in FIG. 5;

FIG. 7 is a perspective view of an insert;

FIG. 8 is a perspective view of a telemetric orthopaedic implant in a third embodiment;

FIG. 9 is a perspective view of the telemetric orthopaedic implant shown in FIG. 8;

FIG. 10 is a perspective view of a telemetric orthopaedic implant illustrating the results of finite element analysis;

FIG. 11 is a graph illustrating data output vs. force;

FIG. 12 is a schematic illustrating an electronic component and a data receiver;

FIG. 13 illustrates use of a handheld device;

FIG. 14 illustrates a control unit;

FIG. 15 is a schematic illustrating a telemetric orthopaedic implant system;

FIG. 16 is a graph illustrating a fracture healing curve;

FIG. 17 is a graph illustrating a non-union fracture healing curve;

FIG. 18 illustrates an artificial fracture gap;

FIG. 19 illustrates an in vitro biomechanical test setup;

FIG. 20 is a graph illustrating strain vs. fracture gap depth as a function of load;

FIG. 21 is a graph illustrating strain vs. load as function of gap volume;

FIG. 22 is a graph illustrating accelerometer output vs. time;

FIG. 23 is a graph illustrating magnitude vs. frequency;

FIG. 24 is a graph illustrating magnitude vs. frequency;

FIG. 25 is a graph illustrating magnitude vs. frequency;

FIG. 26 is a graph illustrating magnitude vs. frequency; and

FIG. 27 is a flowchart illustrating steps to analyze gait.

DETAILED DESCRIPTION OF THE EMBODIMENTS

A “smart implant” is an implant that is able to sense its environment, apply intelligence to determine whether action is required, and act on the sensed information to change something in a controlled, beneficial manner. One attractive application of smart implant subjected to three types of loading: bending, torsional, and compression. These loads may be measured indirectly by measuring sensor output of a series of strain gauges mounted to the orthopaedic implant. In the case of an intramedullary nail, diametrically apposed strain gauges mounted on the outer surfaces of the nail are subjected to tensile and compressive forces, respectively. Typically, the strain measured from the sensors is higher when the implant is loaded in bending than in compression.

A fundamental parameter of the strain gauge is its sensitivity to strain, expressed quantitatively as the gauge factor (G). Gauge factor is defined as the ratio of fractional change in electrical resistance to the fractional change in length (strain),

$\begin{matrix} {G = \frac{\Delta \; R}{R\; ɛ}} & (1) \end{matrix}$

where R=nominal resistance, ΔR=resulting change in resistance and ε=strain. This change in resistance arises from two important factors: (a) the change in the resistivity of the material, and (b) the change in the physical dimensions of the resistor as the material is deformed. For a foil strain gauge, G is found to be 2.1. Voltage recordings are converted to strain using the following equation:—

$\begin{matrix} {{ɛ = {\frac{{- 4}V_{r}}{{GF}\left( {1 + {2V_{r}}} \right)} \times \left( {1 + \frac{R_{L}}{R_{g}}} \right)}},} & (2) \end{matrix}$

where R_(L), is the lead resistance, R_(g) is the nominal gauge resistance, which is specified by the gauge manufacturer, GF is the Gauge Factor, which is also specified by the gauge manufacturer, and V_(r) is the voltage ratio defined by the following equation:—

$\begin{matrix} {V_{r} = \left( \frac{{V_{CH}({strained})} - {V_{CH}({unstrained})}}{V_{EX}} \right)} & (3) \end{matrix}$

where V_(CH) and V_(EX) are the measured signal's voltage and excitation voltage respectively.

Strain is related to stress using Hooke's Law which can be rearranged to calculate the compression and bending loads experienced by the implant (F),

EεA=F,  (4)

where E is the stiffness of the implant in gigapascals (GPa), ε=strain measured from the output of the instrumented implant, and A is the cross-sectional area of the implant in square meters (m²). The corresponding load on the bone could be deduced by subtracting the implant load from the total downward force exerted by the limb measured using either a force plate or a balance.

Incorporation of sensors and other electronic components within an implantable medical device, such as an intramedullary nail, alters its primary function from a passive load-supporting device to a smart “intelligent” system with the ability to record and monitor patient activity and compliance.

Telemetric Intramedullary Nail

Referring to the accompanying drawings in which like reference numbers indicate like elements, FIG. 1 illustrates a telemetric intramedullary QM) nail 10. The telemetric EVI nail 10 includes at least one sensor 12. One particular sensor configuration is illustrated in FIG. 1. In this embodiment, sensors 12 are located in a proximal region 20, a central or mid-shaft region 22, and a distal region 24 of the IM nail 10. In the embodiment depicted in FIG. 1, the telemetric DVI nail 10 includes three sensors 12 a, 12 b, 12 c with a sensor corresponding to each region. However, those of ordinary skill in the art would understand that a greater or lesser number of sensors may be used and that sensors may be applied in other configurations. The telemetric nail 10 continuously measures a set of strain values generated from the sensors 12. As explained in greater detail below, the telemetric IM nail 10 transmits the measurements from the nail to a reader device for calculation of the forces components without disturbing fracture healing.

The telemetric IM nail 10 may include features to allow fixation of the nail to bone. For example, the telemetric IM nail 10 may include proximal apertures 26 and/or distal apertures 28. In the embodiment depicted in FIG. 1, the telemetric IM nail 10 includes two proximal holes 26, a distal hole 28, and a distal slot 28, but those of ordinary skill in the art would understand that a greater or lesser number of apertures may be provided.

As best seen in FIG. 5, the telemetric IM nail 10 also includes one or more electronic components 18, such as a printed circuit board. The electronic components 18 form an instrumentation circuit with the sensors 12. The electronic components 18 may include associated signal conditioning circuitry, one or more microprocessors, one or more memory devices, a power supply, and communications components. The electronic components 18 allow in situ measurement of changes in the local environment. The combination of the sensor 12 and the electronic components 18 provide a powerful tool for indirect measurement of the changing load over time due to fracture consolidation using the algorithm described above. In turn, these indirect measurements may be used to provide information to clinicians on the environment for use in clinical decision making.

In order to maintain the integrity of the telemetric IM nail 10, the implant design must protect the components, provide an accurate and stable connection between the sensor and its environment, and maintain the functionality of the implant itself. Incorporating sensors within the structure of internal implants raises the “packaging problem” of maintaining the insulation of electronics, as biological tissues are an extremely hostile environment. Furthermore, the risk of damage to the electronic components 18 from common sterilization methods cannot be underestimated. Design considerations for instrumenting the IM nail 10 requires minimization of any damage to the mechanical and physical properties of the nail and allow for large scale commercialization and manufacture. Certain designs may be confirmed by measuring the bending stiffness and fatigue behavior of the IM nail 10 before and after instrumentation.

As best seen in FIGS. 2-5, the IM nail 10 includes at least one recess 14. As examples, the recess 14 may be rectangular, square, circular, elliptical, or some combination thereof. The recess 14 may be made using various manufacturing techniques including, but not limited to machining, milling, grinding, forging, casting, stamping, and injection molding. The recess 14 has a depth D, which ranges from about 0.1 mm to about 2.0 mm. The length L of the recess may be in the range from about 1 mm to about 100 mm. In the embodiment depicted in FIG. 3, the recess 14 is about 0.5 mm thick and about 5 mm long. The recess 14 receives the sensor 12 and conductor wires 16. The recess 14 protects the sensor 12 and conductor wires 16 from abrasive damage during the surgical insertion process. The recess 14 is located on either an anterior surface or a posterior surface enabling the sensors 12 to experience tensile and compression forces respectively. The sensor 12 may be fixed in the recess 14 using a range of high stiffness adhesives including epoxy resins, polyurethanes, UV curable adhesives, and medical grade cyanoacrylates. These types of fixation methods do not adversely affect the performance of the sensor 12.

Additionally, the telemetric IM nail 10 may include a recess 14 in the proximal region 20 to receive the electronic components 18. The recess 14 is dimensioned to accept the electronic components 18. For example, the electronic components may be about 56 mm long, about 6.2 mm wide, and about 0.25 mm thick, and the recess 14 is sized accordingly. The recess 14 may be of the same size as the electronic components 18 or slightly larger.

Alternatively, installation of the strain gauges 12 and other electronic components may be carried out using a more evasive method, such as electro-discharge milling a longitudinal section in the implant, installing the components in the IM nail 10, and laser welding the tube segments. However, there are several disadvantages to using this approach. Localized heat of welding tends to cause distortion and warping of the base metals or stresses around the weld area, which could affect the corrosion resistance of the implant. Moreover, laser beam welding has a tremendous temperature differential between the molten metal and the base metal immediately adjacent to the weld. Heating and cooling rates are much higher in laser beam welding than in arc welding, and the heat-affected zones are much smaller. Rapid cooling rates can create problems such as cracking in high carbon steels.

There are a number of ways to encapsulate the sensors 12 and other electronic components. Some components may require more durable methods of encapsulation than others. For example, if a battery or other potentially hazardous device is included in the electronics system a titanium case may be required. Alternatively, if the components are biologically benign, then a simple potting material, such as polyurethane or a silicone, may prove to be sufficient. Those skilled in the art would understand that various materials may be used for the potting material. What is significant is that the potting material acts as a cover to separate the electronic components from the surrounding environment. Soldering and welding techniques may also be used to help permanently seal the sensors 12 and other electronic components inside the instrumented nail 10. Substituting the standard foil gauge with platinum strain gauges may also enhance durability and resistance to sterilization and attack by biological fluids.

In one particular embodiment in FIG. 6, the sensors 12 and the electronic components 18 are covered with a biocompatible potting material 30, such as polyurethane or silicone, in order to provide a hermetic seal. Because the sensors 12 and the electronic components 18 are sealed hermetically from the patient tissues and fluids, long term function of the telemetric IM nail 10 is achievable. At the same time, leakage of non-biocompatible or toxic materials is eliminated. The potting material 30 is an electrically insulative, moisture resistant material, supplied in either a liquid or putty-like form and is used as a protective coating on sensitive areas of electrical and electronic equipment. The potting material 30 may be optically opaque or colorless. The strain gauges 12 and conductor wires 16 are covered in potting material 30 with suitable mechanical characteristics required to survive the implantation process and restore the mechanical envelope.

An alternative arrangement of the electronic components 18 in the telemetric instrumented nail 10 is shown in FIGS. 7, 8, and 9. In this particular design, passive electronic components 40 are located in the recess 14 of the proximal region 20 and active electronic components 42, such as a power supply, microprocessor, data storage device, and external communication device, are contained in a separate nail head insert 44. As best seen in FIG. 9, the passive electronic components 40 may be covered with the potting material 30 to hermetically seal the electronic components 40. In this configuration, the telemetric IM nail 10 is implanted in the usual manner, and, once the nail has been implanted into the bone, the nail head insert 44 is attached to the telemetric IM nail 10. For example, the nail head insert 44 may be threaded into a hole 46 (best seen in FIG. 5). This particular design avoids any sensitive electronics being damaged by the implantation process. Connections between the passive and active electronic components 40, 42 can be made using either an inductively coupled link or physical connections via slip rings.

The telemetric IM nail 10 may be constructed from a biocompatible material using standard manufacturing techniques. For example, the nail may be forged out of metal, hand or machine laid composite, or machined from stock. Alternatively, the telemetric IM nail 10 may be cast, injection molded, or compacted through hot isostatic processing (HIP). The HIP manufacturing process is particularly suited for producing nails with preformed recesses designed to receive sensors and electronic components.

In yet another alternative embodiment, the telemetric IM nail 10 may be constructed using a biodegradable composite whose degradation rate is controlled by sensed strain data. Such a device is more compliant than a conventional metal implant because the mechanical modulus of the implant changes according to the degree of healing of the adjacent bone. Increased load bearing capacity on the healing bone triggers the release of an active agent that accelerates the degradation rate of the nail in order to reduce its load sharing ability. On the other hand, slow healers require the release of active agents that inhibit the degradation rate of the implant material. The release of the active agent may be controlled using a micro-electromechanical structures (MEMS) reservoir system that releases a chemical manipulation on demand that either accelerates or decelerates the rate of degradation of the nail. The instrumented components may be manufactured using restorable materials, such as degradable, porous silicon wafers. Otherwise, non-degradable electronic components may remain in the patient, which may be acceptable in some cases.

FE Modeling to Determine Optimum Position of Sensors

Referring now to FIG. 10, the sensors 12 may be devices capable of measuring mechanical strain, such as foil or semiconductor strain gauges. Alternatively, the sensors 12 may be load cells used to directly measure mechanical load. The embodiment depicted in FIG. 1 utilizes foil strain gauges to measure strain. The optimum location of the sensors 12 for the purpose of measuring strain may be determined through finite element (FE) analysis. The sensors 12 may be located, for example, but not limited to, in the working region of the implant 10. The working region is defined as the region between two fixation apertures 26, 28. The fixation apertures 26, 28 are adapted to receive fasteners, such as screws, to attach the implant 10 to bone. As can be seen in FIG. 10, the darker, shaded areas represent stress concentrations. The stress distribution results from the way in which the nail 10 is loaded through the patient's hip joint and results in high bending stresses on the outer surface of the nail 10, aligned with the proximal apertures 26. Typically, a 50% reduction in stress is observed between sensors placed inside the implant as opposed to an external mounting.

Sensor

The telemetric IM nail 10 includes the sensor 12. The sensor 12 senses at least one item, event, condition, etc. The sensor 12 may be any number of types including, but not limited to, a foil strain gauge, a semi-conductor strain gauge, a vibrating beam sensor, a force sensor, a piezoelectric element, a fibre Bragg grating, a gyrocompass, or a giant magneto-impedance (GMI) sensor. Further, the sensor 12 may indicate any kind of condition including, but not limited to, strain, pH, temperature, pressure, displacement, flow, acceleration, direction, acoustic emissions, voltage, pulse, biomarker indications, such as a specific protein indications, chemical presence, such as by an oxygen detector, by an oxygen potential detector, or by a carbon dioxide detector, a metabolic activity, or biologic indications to indicate the presence of white blood cells, red blood cell, platelets, growth factors, or collagens. Finally, the sensor 12 may be an image capturing device.

Some orthopaedic applications may require more than one sensor to measure more than one item, event, or condition. Thus, some implants require multi-channel capabilities. For example, the telemetric IM nail 10 may include six or more strain gauges. The sensor 12 may be an array of sensors or a series of discrete sensors. The telemetric IM nail 10 also may be designed with multiaxial strain gauges in a rosette configuration to enable loads to be measured in x, y and/or z planes. The configuration of the sensors 12 also may be tailored to meet the requirements of the patients fracture. The sensor 12 is designed in such way that it does not compromise the performance of the implant. For example, the sensor 12 must be unobtrusive, biocompatible, and in no way affect the established biomechanical performance of the implant. It has been shown that nails with a tight fit between implant and the adjacent bone may be deformed significantly during insertion. As a result, the resolution of the selected sensor is better than 8 bit (0.05%). The output of the sensor may be investigated by applying an axial load to the instrumented nail.

The loading configuration is designed to match the loading pattern typically observed in a human femur, i.e. an offset vertical load transmitted through the nail via the proximal fastener. Strain vs. load plots for three instrumented IM nails with two strain sensors 12 located on the inner (compression) and outer (tensile) surfaces at either the mid-shaft region (nail 1), distal region (nail 2), or proximal region (nail 3) respectively are shown in FIG. 11. In all cases, the responses from the sensor pairs are fairly linear when the load on the nail is ramped up to 500 N. In addition, there is little or no hysteresis observed when the load is applied and removed from the nail.

Communication

The electronic components 18 are in communication with a data receiver 50. The electronic components 18 receive data from the sensor 12 and transmit the data to the data receiver 50. The electronic components 18 transmit the data by wire or through a wireless connection. The transmission may use available technologies, such as ZIGBEE™, BLUETOOTH™, Matrix technology developed by The Technology Partnership Plc. (TTP), or other Radio Frequency (RF) technology. ZigBee is a published specification set of high level communication protocols designed for wireless personal area networks (WPANs). The ZIGBEE trademark is owned by ZigBee Alliance Corp., 2400 Camino Ramon, Suite 375, San Ramon, Calif., U.S.A. 94583. Bluetooth is a technical industry standard that facilitates short range communication between wireless devices. The BLUETOOTH trademark is owned by Bluetooth Sig, Inc., 500 108th Avenue NE, Suite 250, Bellevue Wash., U.S.A. 98004. RF is a wireless communication technology using electromagnetic waves to transmit and receive data using a signal above approximately 0.1 MHz in frequency. Due to size and power consumption constraints, the telemetric IM nail 10 may utilize the Medical Implantable Communications Service (MICS) in order to meet certain international standards for communication.

Instrumentation System

FIG. 12 illustrates the electronic components 18, such as a printed circuit board, and the data receiver 50. The electronic component 18 includes a power transmitter 32, a DC power supply 34, a combination analog/digital converter and microprocessor 36, and a sensor data transmitter 38. The data receiver 50 includes a sensor data receiver 52 and a power transmitter 54. Although illustrated as separate components, those of ordinary skill in the art would understand that the transmitter and the receiver may be combined in a single unit, sometimes referred to as a transceiver. In the embodiment depicted in FIG. 12, power consumption and data transmission are contactless. The electronic component 18 may include any of the following: (1) any number of foil strain gauges; (2) matching number of low noise, low power instrumentation amplifiers; (3) matching number of Wheatstone bridge resistor networks; (4) matching number of strain gauge zero-adjustments; and (5) onboard power supply with noise filtering.

Power Management

The telemetric IM nail 10 may incorporate one or more power management strategies. Power management strategies may include implanted power sources or inductive power sources. Implanted power sources may be something simple, such as a battery, or something more complex, such as energy scavenging devices. Energy scavenging devices may include motion powered piezoelectric or electromagnetic generators and associated charge storage devices. Inductive power sources include inductive coupling systems and Radio Frequency (RF) electromagnetic fields.

Finally, the telemetric IM nail 10 may incorporate a storage device (not shown). The storage device may be charged by an inductive/RF coupling or by an internal energy scavenging device. The storage device must have sufficient capacity to store enough energy at least to perform a single shot measurement and to subsequently process and communicate the result.

FIG. 13 illustrates a handheld device 60 being placed on a leg 102 of a patient 100. The handheld device 60 generates RF waves that excite the electronic component 18. The excited electronic component 18 retrieves stored sensor readings and sends them to the handheld device 60 via a carrier wave. The handheld device 60 may be equipped with a processor (not shown) for direct analysis of the sensor readings or the handheld device 60 may be connected to a computer for analysis of the sensor readings.

Communication

The demands on an implantable telemetry system are severe and robust methods must be utilized to capture data from the orthopaedic implant. Prior attempts in the art have not provided a signal in the range needed for an instrumented intramedullary nail. Thus, the telemetric IM nail 10 has a wired interface in its most simplified version. In other words, the electronic components 18 are connected to an external control unit 62 via a wire (not shown). The control unit 62 may be placed on the patient 100 as a wearable device, such as an arm band, wrist band, thigh band, or anklet bracelet. Alternatively, the control unit 62 may be connected to a cast 64, such as by placing the control unit inside the cast or attaching the control unit to the exterior of the cast.

The control unit 62 may include a display 66 and/or a speaker 68. The display 66 may be used to display sensor readings, provide warning lights, a count down timer allowing the patient to anticipate an important event, such as cast removal, or an entertainment device, such as an electronic game, to occupy time. The speaker 68 may be used to provide sounds, such as pre-recorded instruction, warning sounds, or game sounds.

The patient actively wears the control unit 62 which constantly monitors the patient's activity. In the case of a major event, such as a traumatic incident or loss of essential body function, the control unit 62 senses this change and sends out an alert which could be audible and/or visual. Alternatively or in addition to the alert, the control unit 62 may send information to another device which could prompt the wearer for information to confirm the patient's status. The control unit 62 could also be used to notify emergency assistance groups of impending danger and other pertinent information, such as location of the patient. In this last example, the control unit 62 may include a global positioning system (GPS) module to locate the control unit and patient.

The control unit 62 may be housed in virtually any type of material, such as plastic, rubber, metal, glass, ceramic, wood, stone, long fiber composites, short fiber composites, non-fiber composites, etc. The display 66 may be a liquid crystal display, a light emitting diode display, a plasma display, a digital light processing, a liquid crystal on silicon display, cathode ray tube, etc.

In other embodiments, however, the telemetric IM nail 10 has a wireless communications facility to allow the patient to move around freely. This embodiment is partially depicted in FIG. 12.

Not only does the telemetric IM nail 10 include a sensor, but also the telemetric IM nail may include an acting unit to perform certain functions based on sensor readings or external commands. FIG. 15 illustrates a telemetric implant system 110. The telemetric implant system 110 includes a telemetric orthopaedic implant 112, a control unit 114, a reader 116, and a computing device 118. The reader 116 wirelessly communicates with the control unit 114 to transmit and receive data. The reader 116 is connected to the computing device 118 either by wires or wirelessly. The computing device 118 may be any number of known devices, such as a personal digital assistant, a desktop computer, a laptop computer, a notepad PC, a biometric monitoring device, a handheld computer, or a server. The computing device 118 is used to analyze the data received from the orthopaedic implant 112. The computing device 118 may be used to store data and/or to program the telemetric orthopaedic implant 112. The reader 116 and the computing device 118 may be incorporated into a single device.

The orthopaedic implant 112 includes one or more sensors 120, a microcontroller 122, one or more stored deliverables 124, and one or more acting units 126. The sensor 120 outputs an induced signal to a preamplifier (not shown), then to an amplifier (not shown), and then to a filter (not shown). The signal travels then to the microcontroller 122 which processes the sensor signal via an algorithm and decides if the information is to be stored or sent to the acting unit 126. The algorithm used to decide how to act can be pre-programmed from the manufacturer or by surgeon preference. The acting unit 126 may communicate with the microcontroller 122 either by wire or wirelessly. Upon receiving the signal from the control unit 114 or the microcontroller 122, the acting unit 126 deploys a stored deliverable 124, which includes, but is not limited to, biological manipulations, an antibiotic, an anti-inflammatory agent, a pain medication, an osteogenic factor, radio-markers, angiogenic factors, vasodilator, and/or growth factors.

The acting unit 126 may be a MEMS device, such as a pump that delivers a specific volume of medicament or other stored deliverable 124. The orthopaedic implant 112 may include several of these pumps that all contain the same stored deliverable 124 as to offer redundancy in case one or more of the pumps fail. The pump contains a reservoir or reservoirs of stored deliverable 124 to be delivered. The stored deliverable 124 is delivered using any type of microfluidic mechanism, such as a rotary pump, a piston pump, a shape memory material pump, etc.

The control unit 114 includes a power generator 128, an energy storage device 130, a logic circuit 132, a microcontroller 134, an RF detector coil 136, and an RF load switch 138.

User Interface

In some embodiments, the computing device 118 includes a graphical user interface (GUI). The GUI allows a healthcare provider and/or patient to display information based on the collected data either locally or remotely, for example telemedicine, from the telemetric orthopaedic implant 112. The GUI identifies the system to communicate with, prompts the user for security clearance, verifies the security clearance, and downloads the data from the telemetric orthopaedic implant 112 or the reader 116. The data could then be further processed into various forms from simple discrete healing progress status numbers or verbiage to complex information such as a graphical reproduction of the patient gait cycle curve, patient activity, patient compliance, patient data, healthcare provider information, implant manufacture information, surgical techniques, x-radiograph information, computed tomography imaging information, magnetic resonance imaging information.

Further, the patient could be alerted by the GUI as a result of sensed information. The logic circuit 132 may be used to monitor data received from the telemetric orthopaedic implant 112 and send a signal if a certain variable exceeds a preconfigured limit. The alert could let the user know when a clinic visit is necessary for doctor intervention, the device has been overloaded, or how to manage a situation that has occurred without surgeon intervention.

The telemetric implant system 110 has many uses. For example, a patient may undergo a surgical intervention to repair a sustained injury or joint reconstruction, during which time the patient receives a telemetric orthopaedic implant to aid in the repair of the injury. The implant may utilize an electromechanical system designed to monitor various aspects of the patient's recovery with one or more sensors, decide if an action needs to take place, and hence act as programmed.

Early Monitoring of Bone Healing

While immobilization and surgery may facilitate bone healing, the healing of a fracture still requires adequate physiological healing which can be achieved through continuously monitoring changes in the in situ load distribution between the implant and the surrounding bone using sensors and a biotelemetry system. The mass and architecture of bone are known to be influenced by mechanical loading applied to them. In the absence of appropriate loading due to stress shielding caused by poor management of internal orthopaedic fixation systems, bone mass is reduced resulting in compromised healing of the fracture. The primary function of a telemetric orthopaedic implant is to carry the load immediately after surgical placement. For example, the telemetric orthopaedic nail carries the load immediately after surgical placement in the intramedullary canal. With progression of fracture healing, the load sharing between the implant and the bone changes. This can be tracked using strain gauges optimally positioned within the orthopaedic implant according to the location of the fracture. The sensors are used to monitor the progress of union in the case of fracture by continuously monitoring the load component of the healing bone in all spatial components, which is unobtainable from X-rays. Periodic follow-up will provide a graph that shows the gradual decrease of relative motion of the fragments until union occurs.

Each fracture patient generates his or her own unique healing curve; however, the general shape of the healing curve indicates whether the fracture will progress to either a union condition or a non-union condition. The healing curve generated from a patient is dependent upon a number of factors including the type and location of the fracture, health status (underlying disease), age, activity, rehabilitation, and time to reach weight bearing.

Hypothetical load vs. healing time curves showing the loading distribution between an instrumented IM nail and the surrounding bone are schematically illustrated in FIG. 16 and FIG. 17. In FIG. 16, the fracture is progressing to a union condition, and in FIG. 17, the fracture maintains a non-union condition. Although fracture healing results in a reduction in implant load, the remaining load of the nail can be significant and are expected to increase with patient activity. It has been suggested that loading of the bone may increase up to 50% after implant removal. The load measured in the adjacent bone can be determined by subtracting the implant load from the load exerted through the limb, which is determined using either a force plate or balance. The clinician can also measure the load acting through the contralateral limb in order to provide a reference measurement for a fully functional limb.

The healing curve may be used in several different ways. First, in the case of an active telemetric orthopaedic implant, the implant or control unit continuously records data. In the case of an intramedullary nail as an example, the strain on the implant is recorded as the patient ambulates. The surgeon or other healthcare provider may download the data from the implant or control unit in a clinical setting. The data is processed and a healing curve is generated from the data. If the surgeon observes that the strain on the implant is decreasing with time, similar to the graph of FIG. 16, this implies that the surrounding hard tissue is accepting some of the load and, thus, the fracture is healing. However, if the strain on the implant is unchanged with time and at the approximate level as when the patient was discharged from the hospital or other health care facility, similar to the graph of FIG. 17, then this implies that the surrounding hard tissue is not bearing the load and, therefore, the fracture is not healing.

Second, the telemetric orthopaedic implant may be a passive device that does not record data continuously but only when it is exposed to an energy source. In this embodiment, the hospital or healthcare facility provides an energy source which energizes the telemetric orthopaedic implant and allows it to record data. In this example, the telemetric orthopaedic implant is energized, a load is placed on the affected bone with the implant at to a set level, and sensor readings are captured. For example, the implant may be an intramedullary nail and the sensors may measure strain on the nail as the load is applied. The sensed data is downloaded and processed. In this example, the sensed data must be compared to previous measurements. For example, measurements may be taken at predetermined time periods, such as daily or weekly. If the load applied to the bone is unchanged and the strain has decreased compared to previous measurements over time, then it is implied that the hard tissue is sharing some of the load and, thus, the fracture is healing. However, if the strain on the implant remains unchanged compared to previous measurements over time, this implies that the surrounding hard tissues is not bearing any of the load and, therefore, the fracture is not healing.

Telemetric orthopaedic implants of the kind described herein utilize an algorithm that gives an early indication as to whether the fracture will heal or not based on the rate of change in the initial load measurements. The information provided by the sensors also may be used to design a new class of orthopaedic implants that are more compliant with the surrounding bone in terms of strength and stiffness.

The functionality of a telemetric orthopaedic implant may be demonstrated in vitro using a plastic fracture model. In this test shown in FIGS. 18 and 19, a telemetric intramedullary nail 220 is implanted in an intact femur model 200 and gradually, a circumferential fracture gap 210 is introduced while observing changes in the strain as a function of load. Thus, reversing the fracture conditions typically observed in vivo. The strain gauges are applied to the medial and lateral sides of the nail 220, positioned on the shaft of the nail to correspond with the fracture gap placement. Interpretation of the data obtained from this study represents the ability to measure bone healing in vivo. The nail construct is loaded at a stepwise displacement from 0 lbf to 300 lbf in predetermined increments and the strain is measured at each load increment. The first series of strain measurements are made with the bone model completely intact. The next series of strain measurements are made with 75% of the fracture gap 210 in place. Subsequently, the third, fourth, and fifth series of strain measurements are made with 50%, 25%, and 0% of the fracture gap 210 in place, respectively. A final series of strain measurements is made with the fracture gap segments re-inserted to their original position. The fracture gap 210 is approximately 5 mm thick, positioned on the shaft of the bone model such that it will be at half of the working distance of the nail 200, which means it is half of the distance between the locking fasteners.

FIG. 20 illustrates reverse simulated bone healing using an artificially induced circumferential gap. FIG. 21 illustrates load vs. strain curves obtained from the plastic fracture model with 100% (fully intact), 75%, 50%, 25%, and 0% (fully fractured) of the fracture gap in place.

Gait Analysis

The invention also includes a gait analysis tool in which gait data is gathered, processed, and stored until an external device accesses the data and presents it to a reviewer, such as a patient, surgeon, healthcare provider, or physical therapist. The telemetric orthopaedic implant may include an accelerometer, which can output acceleration changes over time at a sampling rate ranging from about 1 to about 2000 Hz. Reference FIG. 22 for an example of graphically represented data output resulting from wearing an accelerometer and the wearer undergoing normal unassisted gait. The sensor output data can then be manipulated as desired for analysis. One such method is to convert the data from the time domain to the frequency domain and look for biometric markers or patterns. FIGS. 23-25 show data similar to that in FIG. 22 transformed into the frequency domain. In these figures, distinct peaks are seen at various frequencies which define the wearer's gait signature seen as the differences in FIGS. 23-25. The patient's gait changes gradually with time and aging or abruptly as would be the case when a patient sustains a severe traumatic injury to any of the bone in their lower extremity. The frequency domain gait signature for an artificially induced antalgic gait pattern is seen in FIG. 26.

The gait analysis tool allows for basic information to be gathered and processed yielding conclusive valuable data with respect to a subject's gait cycle. This data can be used to diagnose the patient's healing status in at least their lower extremities, which when injured impede the normal gait cycle. Historically, surgeons have had to rely on radiographs or other imaging techniques to determine the stage of the patient's bone healing cascade. These tools are helpful but allow for error in diagnosis. There are several areas for this opportunity including but not limited to image quality, parallax, and misdiagnosis. Further, even though these diagnosis tools exist, the surgeon relies on patient testimonial more heavily than the images. The gait analysis tool removes the guessing from the diagnosis by providing the surgeon objective unbiased data collected from the patient throughout the healing process. The gait analysis tool allows the surgeon to understand earlier in the healing process if intervention is needed to augment treatment using a biologic, such as an injectable cement or demineralized bone matrix, to speed healing or if a revision surgery may be necessary. Because the telemetric orthopaedic implant described herein has a memory function, patient data may be stored thus allowing for the easy transmission of the data. This data could include personal data, patient history information, as well as patient activity. If the activity is captured, the surgeon could discern if the patient has been accurately performing postoperative rehabilitation regimens. This allows the surgeon to accurately predict and prescribe further regimens, which currently is not feasible with existing employed technology.

FIG. 27 illustrates steps to implement gait analysis. A person, such as a doctor or healthcare provider, begins at step 310. Instep 312, the person reads the data from the patient. For example, the patient may have an active telemetric orthopaedic that continuously measures data as the patient ambulates. In the case of an intramedullary nail as an example, the acceleration of the implant is recorded as the patient ambulates. The surgeon or other healthcare provider may download the data from the implant or control unit in a clinical setting. After the data is downloaded, it is processed in step 314 to convert the data from the time domain to the frequency domain. This allows the doctor, healthcare provider, or software to look for biometric markers or patterns.

Because data is continuously monitored, extraneous data is also downloaded in step 312. For example, data may be recorded when the patient is sitting. In optional step 316, a decision is used to look for peak stride and peak step data within the global download. By utilizing the decision 316, it can be ensured that gait information is present in the global data. If gait information is not present, the doctor or healthcare provider returns to step 312 at another time to retrieve global data.

In steps 318 to 332, the gait information is extracted and placed into groups for analysis. In this way, it can be ensured that the doctor or healthcare provider is looking at how the gait changes from one group to the next. For example, the first group of gait information may be from a first time period and the second group of gait information may be from a second time period.

In step 318, stride amplitude, step amplitude, stride frequency, and step frequency is estimated. In step 320, a simplified single gait cycle group is generated. The global data is broken down and correlated to the simplified single gait cycle group in step 322. The data is processed iteratively in step 324. In step 326, a decision is made whether the correlation is above an adaptive threshold. If so, the correlated cycle is identified as a gait group in step 330. If not, the cycle is determined to be non-gait data in step 328. The data is processed iteratively until all the data is analyzed as being gait data or non-gait data in step 332. Once the gait cycles are identified, the gait cycles are analyzed in step 334 and the process completes in step 336.

Alternatively, gait data may be collected and analyzed at the hospital or healthcare facility. In other words, the patient ambulates and data is recorded in the presence of a doctor or healthcare provider. However, this type of data collection does not allow for analysis over long periods of time. Moreover, this type of data collection does not allow for measurement of patient compliance because a patient is more likely to be non-compliant when outside of the hospital or healthcare facility and compliant when in the presence of the doctor or healthcare provider. However, gait data taken at discrete periods of time still provide an indication whether or not a fracture is progressing to a union condition.

CONCLUSION

Although the depicted embodiments concentrate on the function of an instrumented intramedullary nail designed specifically for bone healing, alternative embodiments include incorporation of the sensor and other electronic components within other implantable trauma products, such as a plate, a bone screw, a cannulated screw, a pin, a rod, a staple and a cable. Further, the instrumentation described herein is extendable to joint replacement implants, such a total knee replacements (TKR) and total hip replacements (THR), dental implants, and craniomaxillofacial implants.

A patient receives a wireless instrumented joint reconstruction product. The electromechanical system within the implant may be used to monitor patient recovery using one or more sensors, and make a decision as to whether any intervention is required in the patient's rehabilitation. The telemetric joint replacement continuously measures a complete set of strain values generated in the implant and transmits them from the patient to a laboratory computer system without disturbing the primary function of the implant. Alternatively, a wired system may be utilized in the form of a wearable device external to the patient. Again, the electromechanical system could be designed to monitor various aspects of the patient's recovery.

The wireless technology may be introduced into dental implants to enable early detection of implant overloading. Overloading occurs when prolonged excessive occlusal forces applied to the implant exceeded the ability of the bone-implant interface to withstand and adapt to these forces, leading to fibrous replacement at the implant interface, termed “osseodisintegration,” and ultimately to implant failure. Again, a communication link may be used to selectively access the strain data in the memory from an external source.

The technology associated with the instrumentation procedure also may be adapted to monitor soft tissue repair (e.g. skin muscle, tendons, ligaments, cartilage etc.) and the repair and monitoring of internal organs (kidneys, liver, stomach, lungs, heart, etc.).

The advantage of the invention over the prior art concerns the incorporation of the components within the fixation device in a manner that protects the components, provides an accurate and stable connection between the sensor and its environment, maintains the functionality of the implant itself, and is suitable for large scale manufacture. The device allows for information to be gathered and processed yielding useful clinical data with respect to a patient's bone healing cascade.

The instrumented device removes the guessing from the conventional diagnostic techniques, such as x-ray, CT and MRI imaging, by providing the patient objective quantitative data collected from them through the healing process. Currently, there is no device which quantifies the skeletal loads encountered during fracture healing, as well as during different patient and physiotherapy activities. Furthermore, the load distribution between the implant and the adjacent bone during fracture healing is also unknown. Such data would help to optimize postoperative protocols for improved fracture healing. The device described herein addresses this by having on board sensors and a memory facility enabling patient data to be stored thus allowing for early transmission of data. This data includes patient history and patient activity. The device also enables early intervention by the surgeon, if required, such as administration of drugs, injection of orthobiologics, cements or demineralized bone matrix to help promote/accelerate bone healing or a revision surgery.

In view of the foregoing, it will be seen that the several advantages of the invention are achieved and attained. Among other things, potential clinical benefits include reduced number of clinic visits, reduced pain suffered by the patient, improved data on fracture healing, and early notification of delayed or non-union.

The embodiments were chosen and described in order to best explain the principles of the invention and its practical application to thereby enable others skilled in the art to best utilize the invention in various embodiments and with various modifications as are suited to the particular use contemplated.

As various modifications could be made in the constructions and methods herein described and illustrated without departing from the scope of the invention, it is intended that all matter contained in the foregoing description or shown in the accompanying drawings shall be interpreted as illustrative rather than limiting. Thus, the breadth and scope of the present invention should not be limited by any of the above-described exemplary embodiments, but should be defined only in accordance with the following claims appended hereto and their equivalents. 

1. An orthopaedic implant comprising: a shaft comprising a biodegradable composite; and a strain sensor; wherein the orthopaedic implant is configured to alter a degradation rate of the biodegradable composite based on strain data generated by the strain sensor.
 2. The orthopaedic implant of claim 1, wherein the orthopaedic implant is configured such that, when implanted in bone, the orthopaedic implant changes a mechanical modulus of the shaft according to a degree of healing of the bone.
 3. The orthopaedic implant of claim 1, further comprising a reservoir containing a chemical agent that accelerates degradation of the biodegradable composite; wherein the orthopaedic implant is configured to release the chemical agent in response to an increase in load bearing capacity of bone near the implant to accelerate degradation of the biodegradable composite.
 4. The orthopaedic implant of claim 1, further comprising a reservoir containing a chemical agent that inhibits degradation of the biodegradable composite; wherein the orthopaedic implant is configured to release the chemical agent to inhibit degradation of the biodegradable composite.
 5. The orthopaedic implant of claim 1, wherein the orthopaedic implant is an intramedullary nail.
 6. The orthopaedic implant of claim 1, wherein the orthopaedic implant comprises one or more electronic components that comprise degradable porous silicon wafers.
 7. The orthopaedic implant of claim 1, further comprising one or more pumps configured to deliver a specific volume of a chemical agent.
 8. An orthopaedic implant comprising: a shaft having an outer surface and defining a recess in the outer surface; at least one sensor located in the recess; a microprocessor in communication with the at least one sensor; a transmitter to transmit data generated by the at least one sensor; and an acting unit in communication with the microprocessor such that the acting unit is configured to perform an action in response to receiving an input.
 9. The orthopaedic implant of claim 8, wherein the acting unit is configured to deploy a stored deliverable based on receiving the input.
 10. The orthopaedic implant of claim 9, wherein the stored deliverable comprises one or more of a biological manipulation, an antibiotic, an anti-inflammatory agent, a pain medication, an osteogenic factor, a radio-marker, an angiogenic factor, a vasodilator, and a growth factor.
 11. The orthopaedic implant of claim 8, wherein: the shaft has a longitudinal axis, and the recess has a length along the longitudinal axis of between about 1 millimeter to about 100 millimeters; and the recess has a depth of between about 0.1 millimeters to about 2.0 millimeters.
 12. The orthopaedic implant of claim 11, wherein: the length of the recess is about 5 millimeters; and the recess has a width perpendicular to the length and the depth of about 0.5 millimeters.
 13. The orthopaedic implant of claim 8, wherein the shaft comprises a composite material.
 14. The orthopaedic implant of claim 8, wherein the transmitter is configured to wirelessly transmit the data generated by the at least one sensor.
 15. The orthopaedic implant of claim 8, wherein the at least one sensor comprises a plurality of multiaxial strain gauges arranged in a rosette configuration.
 16. An orthopaedic implant comprising: a first portion comprising first electronic components that include at least one passive sensor; and a second portion removably attachable to the first portion, the second portion comprising second electronic components that include a microprocessor, a transmitter, and a power supply, the second portion being removeably attachable to the first portion after implantation of the first portion in a bone such that the first electronic components are in communication with the second electronic components when the first portion is attached to the second portion.
 17. The orthopaedic implant of claim 16, wherein the first portion is an intramedullary nail and the second portion is a nail head insert.
 18. The orthopaedic implant of claim 16, wherein the first portion has a proximal end and defines a hole at the proximal end, and the second portion is configured for attachment to the first portion at the hole.
 19. The orthopaedic implant of claim 16, wherein the first portion has an outer surface and defines a recess in the outer surface, and the at least one passive sensor is located in the recess.
 20. The orthopaedic implant of claim 16, wherein the first electronic components and the second electronic components are connected by an inductively coupled link or a physical connection. 